--- /dev/null
+\documentclass{scdpg}
+\begin{document}
+\scBookLanguage{de}
+\begin{scAbstract}
+\scLanguage{en}
+\scTitle{DAQ Monitoring and Controlling -- A web-based approach}
+\scAuthor{*}{Manuel}{Penschuck}{1}
+\scAuthor{}{Jan}{Michel}{1}
+\scAuthor{}{Michael}{Wiebusch}{1}
+\scAuthor{}{Joachim}{Stroth}{1}
+\scAuthor{}{Michael}{Traxler}{2}
+\scAffiliation{1}{Goethe-Universit\"at, Frankfurt}
+\scAffiliation{2}{GSI Gesellschaft f\"ur Schwerionenforschung, Darmstadt}
+
+\scBeginText
+In the scope of experimental set-ups for the upcoming FAIR experiments,
+a FPGA-based general purpose trigger and read-out board (TRB3) has been
+developed which is already in use in several detector set-ups (e.g.
+HADES, CBM-MVD, PANDA). For on- and off-board communication between the
+DAQ's subsystems, TrbNet, a specialised high-speed, low-latency network
+protocol developed for the DAQ system of the HADES detector, is used.
+Communication with any computer infrastructure is provided by Gigabit
+Ethernet.
+
+Monitoring and configuration of all DAQ systems and front-end electronics
+is consistently managed by the powerful slow-control features of TrbNet and
+supported by a flexible and mature software tool-chain, designed to met the
+diverse requirements during development and setting-up and beam-time. Most
+building blocks offer a graphical-user-interface (GUI) implemented using
+omnipresent web 2.0 technologies, which enable rapid prototyping, network
+transparent access and impose minimal software dependencies on the client's
+machine.
+
+This contribution will present the GUI-related features and infrastructure
+highlighting the multiple interfaces from the DAQ's slow-control to the
+client's web-browser.
+\scEndText
+\scConference{Frankfurt 2014}
+\scPart{HK}
+\scContributionType{Poster}
+\scTopic{Instrumentierung}
+\scEmail{manuel.penschuck@stud.uni-frankfurt.de}
+\scCountry{Germany}
+\end{scAbstract}
+\end{document}
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